Piezoelectric Power Generation System

What is claimed is: 1 . A piezoelectric power generation system, comprising: a power generation device comprising: a stator comprising an internal surface, the internal surface defining an internal orifice; one or more piezoelectric power generation elements disposed on the internal surface of the stator; a rotor disposed within the internal orifice comprising one or more lobes formed on an outside surface of the rotor, wherein the rotor is configured to rotate with respect to the stator and the one or more piezoelectric power generation elements, wherein the one or more lobes contact the one or more piezoelectric power generation elements as the one or more lobes rotate past the one or more piezoelectric power generation elements, and wherein the one or more piezoelectric power generation elements generate energy when contacted by the one or more lobes; an impeller coupled to the rotor and configured to rotate the rotor when the impeller is actuated by a flow of fluid; and a power storage device configured to store energy generated by the one or more piezoelectric power generation elements. 2 . The piezoelectric power generation system of claim 1 , wherein the one or more piezoelectric power generation elements comprise one or more stacked piezoelectric elements, wherein the one or more lobes impart a normal force onto the one or more stacked piezoelectric elements when the one or more lobes rotate past the one or more stacked piezoelectric elements. 3 . The piezoelectric power generation system of claim 1 , wherein the one or more piezoelectric power generation elements comprise one or more flexible piezoelectric sheets which extend from the stator towards the rotor, and wherein the one or more lobes cause the one or more flexible piezoelectric sheets to bend when the one or more lobes rotate past the one or more flexible piezoelectric sheets. 4 . The piezoelectric power generation system of claim 3 , wherein the one or more flexible piezoelectric sheets each comprise an outer tip having a wear-resistance material. 5 . The piezoelectric power generation system of claim 1 , wherein the one or more lobes have at least one of a rounded shape, a triangular shape, or a gear-tooth shape. 6 . The piezoelectric power generation system of claim 1 , wherein the rotor comprises a central opening configured to receive a pipe. 7 . The piezoelectric power generation system of claim 1 , wherein the rotor comprises a central opening configured to receive fluid flow therethrough. 8 . The piezoelectric power generation system of claim 1 , further comprising a housing in which the power generation device is disposed, wherein the housing isolates the power generation device from the flow of fluid. 9 . The piezoelectric power generation system of claim 1 , wherein the one or more lobes are formed integrally with the rotor. 10 . The piezoelectric power generation system of claim 1 , wherein the one or more lobes include one or more rollers disposed in one or more respective roller holders formed in the rotor, and wherein the one or more rollers spin freely within the roller holders. 11 . A piezoelectric power generation device, comprising: a stator comprising an internal surface, the internal surface defining an internal orifice; one or more piezoelectric power generation elements disposed on the internal surface of the stator; a rotor disposed within the internal orifice comprising one or more lobes formed on an outside surface of the rotor, wherein the rotor is configured to rotate with respect to the stator and the one or more piezoelectric power generation elements, wherein the one or more lobes contact the one or more piezoelectric power generation elements as the one or more lobes rotate past the one or more piezoelectric power generation elements, and wherein the one or more piezoelectric power generation elements generate energy when contacted by the one or more lobes. 12 . The piezoelectric power generation device of claim 11 , wherein the one or more piezoelectric power generation elements comprise one or more stacked piezoelectric elements, and wherein the one or more lobes impart a normal force onto the one or more stacked piezoelectric elements when the one or more lobes rotate past the one or more stacked piezoelectric elements. 13 . The piezoelectric power generation device of claim 11 , wherein the one or more piezoelectric power generation elements comprise one or more flexible piezoelectric sheets which extend from the stator towards the rotor, and wherein the one or more lobes cause the one or more flexible piezoelectric sheets to bend when the one or more lobes rotate past the one or more flexible piezoelectric sheets. 14 . The piezoelectric power generation device of claim 11 , further comprising an impeller coupled and disposed within to the rotor, wherein actuation of the impeller rotates the rotor. 15 . The piezoelectric power generation device of claim 11 , further comprising a propeller coupled to the rotor, wherein actuation of the propeller rotates the rotor. 16 . The piezoelectric power generation device of claim 12 , further comprising a protective layer disposed between the one or more stacked piezoelectric elements and the one or more lobes, wherein the protective layer transfers the normal force applied by the one or more lobes to the one or more stacked piezoelectric elements. 17 . The piezoelectric power generation device of claim 11 , wherein the stator and the rotor are both cylindrically shaped. 18 . A piezoelectric power generation device, comprising: a rotor comprising an internal surface, the internal surface defining an internal orifice, wherein one or more lobes are disposed on the internal surface; a stator disposed within the internal orifice, the stator comprising an outer surface; and one or more piezoelectric power generation elements disposed on the outer surface of the stator towards the internal surface of the rotor, wherein the rotor is configured to rotate around the stator and the one or more piezoelectric power generation elements, wherein the one or more lobes contact the one or more piezoelectric power generation elements as the one or more lobes rotate past the one or more piezoelectric power generation elements, and wherein the one or more piezoelectric power generation elements generate energy when contacted by the one or more lobes. 19 . The piezoelectric power generation device of claim 18 , wherein the one or more piezoelectric power generation elements comprise one or more stacked piezoelectric elements, and wherein the one or more lobes impart a normal force onto the one or more stacked piezoelectric elements when the one or more lobes rotate past the one or more stacked piezoelectric elements. 20 . The piezoelectric power generation device of claim 18 , wherein the one or more piezoelectric power generation elements comprise one or more flexible piezoelectric sheets which extend from the stator towards the rotor, and wherein the one or more lobes cause the one or more flexible piezoelectric sheets to bend when the one or more lobes rotate past the one or more flexible piezoelectric sheets. 21 . The piezoelectric power generation device of claim 19 , further comprising a protective layer disposed between the one or more stacked piezoelectric elements and the one or more lobes, wherein the protective layer transfers the normal force applied by the one or more lobes to the one or more stacked piezoelectric e